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March 6, 2026Open Access

The Information Equilibrium of the Riemann Zeta Function via Adelic Spectral Stability and Algorithmic Incompressibility

Key Points

The central goal is to formally prove the Riemann Hypothesis by establishing an Information Equilibrium in the critical strip.
Synthesized Adelic Analysis with Algorithmic Information Theory.
Proved consistency of the zeta function's zeros using Adelic Spectral Stability.
Applied Kolmogorov complexity to analyze deviations from the critical line.
Demonstrated that non-trivial zeros of the Riemann zeta function have a real part of exactly 1/2.
Showed that deviations from the critical line would disrupt prime distribution's logical density.

Abstract

Abstract: This manuscript provides a formal proof of the Riemann Hypothesis by establishing an Information Equilibrium within the critical strip. By synthesizing Adelic Analysis and Algorithmic Information Theory, the author demonstrates that the non-trivial zeros of the Riemann zeta function must possess a real part of exactly 1/2. Key Frameworks: Adelic Spectral Stability: Utilizing the ring of adeles to ensure the global consistency of the zeta function's zeros. Algorithmic Incompressibility: Applying Kolmogorov complexity to prove that any deviation from the critical line would violate the logical density of prime distribution. Author Note: The author is an independent researcher (secondary school student) specializing in the intersection of number theory and computational logic. This work offers a novel "Stability-Complexity" bridge to one of the most enduring problems in mathematics.

The Information Equilibrium of the Riemann Zeta Function via Adelic Spectral Stability and Algorithmic Incompressibility

Key Points

Abstract

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